Analysis of a glucose-containing tetrasaccharide by high-performance liquid affinity chromatography

In the present work we have explored conditions for using a pulsed amperometric detector for on-line analysis of oligosaccharides eluted from a high-performance liquid affinity chromatography column. A monoclonal antibody that specifically binds a glucose-containing oligosaccharide is coupled to a SelectiSphere-10-activated tresyl column. The system is eluted isocratically and easily detects 10 ng of the oligosaccharide with a linear response up to 250 ng. Analysis of both serum and urine samples from normal individuals and patients with acute pancreatitis gives a single retarded peak with a retention time identical to that of authentic (Glc)4. Retarded material pooled from several analyses of urine was positively identified as (Glc)4 by GC-MS analysis. As this method requires little cleanup and no chemical derivitization of the sample and is performed rapidly (less than 20 min) at sensitivities of at least 10 micrograms/liter in biological fluids, it represents a substantial improvement over previous GC-MS, radioimmunoassay, and enzyme-linked immunoadsorbent assay methods used to determine (Glc)4.     

Detection and isolation of oligosaccharides with Lea and Leb blood group activities by affinity chromatography using monoclonal antibodies

Affinity columns prepared by immobilizing monoclonal antibodies that specifically recognize the Lea or the Leb blood group antigens can be used for analytical or preparative isolation of oligosaccharides with the corresponding reactivities. The number of immobilized functional antibody combining sites on a column and the dissociation constants for standard oligosaccharides are determined by frontal analysis. By employing a simple approximation [K.-I. Kasai et al. (1986) J. Chromatogr. 376, 33-47] these parameters can be used to rationally design columns with properties appropriate for zonal affinity chromatography. The affinity for binding of the Lea-active oligosaccharide lacto-N-fucopentaose II (LNF II) by the anti-Lea antibody CO-514 doubles for each 8 degrees C downward shift in temperature between 37 and 4 degrees C. By zonal chromatography, Lea- or Leb-active oligosaccharides are recovered from a complex mixture of milk oligosaccharides containing more than a 20-fold molar excess of structurally similar but antigenically distinct oligosaccharides. The capacity for preparative isolation of an oligosaccharide increases in a linear fashion with the amount of antibody loaded on the solid support. The monoclonal antibodies used in these studies are products of hybridomas derived from mice immunized with human colorectal carcinoma cell lines [M. Blaszczyk et al. (1984) Arch. Biochem. Biophys. 233, 161-168]. The experiments establish that affinity chromatography applied to mixtures of oligosaccharides released by enzymatic or chemical cleavage of glycoconjugates may simplify the task of isolating and characterizing biologically interesting target antigens of monoclonal antibodies.     

Monoclonal antibodies specific for oligosaccharides prepared by partial nitrous acid deamination of heparin

Monoclonal antibodies were raised against a conjugate between heparin oligosaccharides and human serum albumin. The oligosaccharides were prepared by partial nitrous acid degradation of heparin and were coupled to human serum albumin by reductive amination. Characterization of the antibodies secreted by one of the resulting clones showed that they recognize a determinant present in the oligosaccharide antigen, but not in intact heparin, nor in a variety of related polysaccharides. Degradation of heparin by nitrous acid generates a 2,5-anhydro-D-mannose residue at the reducing end of the resulting oligosaccharides, and it is concluded that this structure is essential for interaction with the antibodies. Reduced oligosaccharides (containing a terminal anhydromannitol residue) are also active. After gel chromatography of partially degraded heparin, the smallest components capable of binding to the antibodies were found in a tetrasaccharide fraction. Affinity chromatography on immobilized monoclonal antibodies separated this tetrasaccharide fraction into distinct populations of binding and nonbinding species. Structural analysis showed that the tetrasaccharide fraction that bound to the monoclonal antibodies contained one single component with the structure IdoA(2-OSO3)-GlcNSO3 (6-OSO3)-IdoA(2-OSO3)-aManR(6-OSO3), whereas the fraction that did not bind to the antibodies contained a mixture of different structures.     

Mismatch Repair Mutations of ESCHERICHIA COLI K12 Enhance Transposon Excision

Excision of the prokaryotic transposon Tn10 is a host-mediated process that occurs in the absence of recA function or any transposon-encoded functions. To determine which host functions might play a role in transposon excision, we have isolated 40 mutants of E. coli K12, designated tex, which increase the frequency of Tn10 precise excision. Three of these mutations (texA) have been shown to qualitatively alter RecBC function. We show that 21 additional tex mutations with a mutator phenotype map to five genes previously identified as components of a methylation-directed pathway for repair of base pair mismatches: uvrD, mutH, mutL, mutS and dam. Previously identified alleles of these genes also have a Tex phenotype.--Several other E. coli mutations affecting related functions have been analyzed for their effects on Tn10 excision. Other mutations affecting the frequency of spontaneous mutations (mutT, polA, ung), different excision repair pathways (uvrA, uvrB) or the state of DNA methylation (dcm) have no effect on Tn10 excision. Mutations ssb-113 and mutD5, however, do increase Tn10 excision.--The products of the mismatch correction genes probably function in a coordinated way during DNA repair in vivo. Thus, mutations in these genes might also enhance transposon excision by a single general mechanism. Alternatively, since mutations in each gene have qualitatively and quantitatively different effects on transposon excision, defects in different mismatch repair genes may enhance excision by different mechanisms.     

Interaction of substrates with glutamine synthetase after limited proteolysis

Previous studies [Dautry-Varsat, A., Cohen, G. N., & Stadtman, E.R. (1979) J. Biol. Chem. 254, 3124-3128; Lei, M., Aebi, U., Heidner, E. G., & Eisenberg, D. (1979) J. Biol. Chem. 254, 3129-3134] have shown that Escherichia coli glutamine synthetase (GS) can be cleaved by proteases to form a limited digestion species called nicked glutamine synthetase (GS). The present study gives the amino acid sequence of the protease-sensitive region of glutamine synthetase. The present study also shows that GS is enzymatically active, but this activity is low compared to the activity of GS. The apparent Michaelis constant value for glutamate was 90 mM for GS as compared to 3 mM for GS, while the Michaelis constant values for ATP were similar for GS and GS*. The dissociation constant values for ATP, as determined by intrinsic fluorescence measurements, were similar for GS and GS*. Glutamate decreased the dissociation constant value of ATP for GS because of synergism between the two binding sites; glutamate did not decrease the dissociation constant value of ATP for GS*. The glutamate analogue methionine sulfoximine bound very tightly to GS and inactivated the enzyme in the presence of ATP. Methionine sulfoximine did not appear to bind to GS* and did not inactivate GS* in the presence of ATP. The ATP analogue 5'-[p-(fluorosulfonyl)benzoyl]adenosine bound to GS and inactivated the enzyme by forming a covalent bond with it. Glutamate accelerated this inactivation because of the synergism between the ATP and glutamate binding sites of GS.(ABSTRACT TRUNCATED AT 250 WORDS)     

A new non-equilibrium enzyme linked immunosorbent assay for a glycogen-derived urinary tetrasaccharide

The tetrasaccharide, Glc1-6Glc1-4Glc1-4Glc, denoted (Glc)₄, is a limit dextrin formed by amylolytic degradation of glycogen. In order to evaluate the possible clinical importance of (Glc)₄ excretion as an indicator of certain physiological and pathological conditions, we have developed a new rapid and inexpensive immunoassay using a monoclonal antibody raised against (Glc)₄ glycosidically-linked to a carrier protein. As the antibody is highly specific, it can be used to measure native (Glc)₄ directly, without the chemical reduction step required in previous methods. A new type of non-equilibrium ELISA inhibition test was developed based on the capacity of free (Glc)₄ to decrease initial rates of antibody binding to (Glc)₄-coated microtiter wells. The method is highly reproducible and is as sensitive and accurate as the gas chromatography method or radioimmunoassay used previously.Abbreviations (Glc)₄ Glc1-6Glc1-4Glc1-4Glc - KLH keyhole limpet hemacyanin - BSA bovine serum albumin - PEG polyethylene glycol     

Senescence Mutants of Saccharomyces Cerevisiae with a Defect in Telomere Replication Identify Three Additional Est Genes

The primary determinant for telomere replication is the enzyme telomerase, responsible for elongating the G-rich strand of the telomere. The only component of this enzyme that has been identified in Saccharomyces cerevisiae is the TLC1 gene, encoding the telomerase RNA subunit. However, a yeast strain defective for the EST1 gene exhibits the same phenotypes (progressively shorter telomeres and a senescence phenotype) as a strain deleted for TLC1, suggesting that EST1 encodes either a component of telomerase or some other factor essential for telomerase function. We designed a multitiered screen that led to the isolation of 22 mutants that display the same phenotypes as est1 and tlc1 mutant strains. These mutations mapped to four complementation groups: the previously identified EST1 gene and three additional genes, called EST2, EST3 and EST4. Cloning of the EST2 gene demonstrated that it encodes a large, extremely basic novel protein with no motifs that provide clues as to function. Epistasis analysis indicated that the four EST genes function in the same pathway for telomere replication as defined by the TLC1 gene, suggesting that the EST genes encode either components of telomerase or factors that positively regulate telomerase activity.     

Increased urinary excretion of free N-acetylneuraminic acid in thirteen patients with Salla disease

Thirteen severely retarded patients with Salla disease, a new type of lysosomal storage disorder, have been studied biochemically. All patients excreted approximately ten times more free sialic acid than normal individuals. The isolated sialic acid was characterized by paper chromatography, thin-layer chromatography, optical rotation, 13C and 1H nuclear magnetic resonance spectroscopy, and mass spectrometry of its permethylated derivative. The results clearly indicated that the excreted sialic acid was identical to N-acetylneuraminic acid. The main sialylated trisaccharide present in the urine of the patients was identified as 3'-sialyllactose by sugar and methylation analysis. The excreted amounts were found to be within normal range.